Faculty Bibliography

BACKGROUND: Long considered to be inert organelles for lipid storage, lipid droplets (LDs) have recently attracted great interest as dynamic structures central to cellular lipid and energy metabolism. hypoxia-inducible gene (HIG2) and perilipin 2 (PLIN2, adipophilin) are LD-associated proteins known to be upregulated by hypoxia (Bensaad, 2014) and/or following von Hippel-Lindau (VHL) gene inactivation (Togashi, 2005; Yao, 2005). We sought to determine whether overexpression of HIG2 and PLIN2 in response to hypoxia or pseudohypoxia may be involved in these histopathologic features of glioma and hemangioblastoma. METHODS: Tumor specimens from 12 patients with glioma grade II-IV (age 3-59 y) and 23 patients with CNS hemangioblastoma (age 15-63 y) were analyzed by immunohistochemistry (IHC) to delineate their expression of HIG2 and PLIN2. To evaluate the role of hypoxia, glioblastoma (GBM) tissues (n = 2) were double-label immunostained for HIF-1alpha and PLIN2 (Zagzag, 2008). Additionally, cultures of tumor spheres isolated from GBM patients (n = 2) (Bayin, 2014) were exposed to hypoxic (1% O2) conditions for 24-72 h, and the cell proteins analyzed by Western blots. RESULTS: HIG2 and PLIN2 were consistently expressed on LDs in hypoxic glioma tumor cells, including pseudopalisading cells in GBMs, but not in adjacent hyperplastic vessels, inflammatory cells or normal brain tissue, independently of tumor grade or the presence of IDH1 (n = 3) and/or TP53 (n = 7) mutations. Likewise, LDs in stromal tumor cells in hemangioblastoma were intensely immunopositive for HIG2 and PLIN2. Double-label IHC showed tight co-expression of HIF-1a and PLIN2 in glioma tumor cells, consistent with the hypoxic regulation of PLIN2. Similarly, expression of HIF-1a and HIG2 proteins was upregulated in GBM tumor spheres under hypoxic conditions. CONCLUSIONS: Our results suggest that HIG2 and PLIN2 are involved in the hypoxic adaptation of lipid metabolism during tumorigenesis, and may serve as specific biomarkers of glioma tumor cells and stromal cells in CNS hemangioblastoma

A major impeding factor in designing effective therapies against glioblastoma (GBM) is its extensive molecular heterogeneity and the diversity of microenvironmental conditions within any given tumor. To test whether heterogeneity with the GBM stem cell (GSC) population is required to ensure tumor growth in such diverse microenvironments, we used human GBM biospecimens to examine the identity of cells marked by two established GSC markers: CD133 and activation of the Notch pathway. Using primary GBM cultures engineered to express GFP upon activation of Notch signaling, we observed only partial overlap between cells expressing cell surface CD133 and cells with Notch activation (n = 3 specimens), contrary to expectations based on prior literature. To further investigate this finding, we FACS-isolated these cell populations and characterized them. While both CD133+ (CD133 + /Notch-) and Notch+(CD133-/Notch+) cells fulfill GSC criteria, they differ vastly in their transcriptome, metabolic preferences and differentiation capacity, thus giving rise to histologically distinct tumors. CD133+ GSCs have increased expression of hypoxia-regulated and glycolytic genes, and are able to expand under hypoxia by activating anaerobic glycolysis. In contrast, Notch+ GSCs are unable to utilize anaerobic glycolysis under hypoxia, leading to decreased tumorsphere formation ability. While CD133+ GSCs give rise to histologically homogeneous tumors devoid of large tumor vessels, tumors initiated by Notch+ GSCs are marked by large perfusing vessels enveloped by pericytes. Using a lineage tracing system, we showed that pericytes are derived from Notch+ GSCs. In addition, Notch+ cells are able to give rise to all tumor lineages in vitro and in vivo, including CD133 + /Notch- cells, as opposed to Notch- populations, which have restricted differentiation capacity and do not generate Notch+ lineages. Our findings demonstrate that GSC heterogeneity is a mechanism used by tumors to sustain growth in diverse microenvironmental conditions

Intratumoral heterogeneity in glioblastoma (GBM) is exemplified by the diversity of tumor microenvironments, which include normoxic hypervascular areas and necrotic regions, which are considered hypoxic. GBM stem cells (GSCs) play a central role in tumor growth and therapy resistance. How GSCs adapt to diverse GBM microenvironments remains an important and unanswered question. We recently discovered that CD133-expressing GSCs are metabolically adept at expanding in hypoxic conditions and do not require Notch signaling for their self-renewal. Transcriptional analysis indicated that CD133+ GSCs have 17.8+/-8.8-fold enriched expression of GPR133 (n = 3 biospecimens), a member of the adhesion family of Gproteincoupled receptors. Immunostaining with GPR133 antibody revealed that GPR133 expression is restricted to hypoxic regions within GBM tumors (12/12 GBM biospecimens) and not present in normal brain. We observed that GPR133 mRNA expression correlates with hypoxia-induced transcripts, such as CA9 and VEFGA (n = 3 primary cultures). To test the hypothesis that GPR133 expression is regulated by oxygen tension, we subjected GBM cultures to 1% O2 in vitro and found that GPR133 transcript was consistently upregulated (n = 5 cultures). To examine whether GPR133 is important for GSC self-renewal, we tested the effect of shRNA-mediated knockdown on in vitro tumorsphere formation ability. GPR133 knockdown depleted CD133+ GSCs and inhibited tumorsphere formation under both normoxic and hypoxic conditions (p< 0.05). GPR133 knockdown also reduced in vivo tumorigenicity and increased survival of implanted mice (n = 3). Using colorimetric assays, we found that CD133+ GSCs have 26.2+/-12.53% higher cAMP levels compared to CD133- GBM cells (n = 3) and that GPR133 knockdown downregulated cAMP levels to 47.25+/-27.27% of scramble control (n = 3), suggesting that GPR133 signals through activation of adenylate cyclase and cAMP elevation

BACKGROUND AND PURPOSE: The purpose of this study was to investigate imaging correlates to the changes occurring during angiogenesis in gliomas. This was accomplished through in vivo assessment of vascular parameters (relative CBV and permeability surface-area product) and their changing relationship with increasing glioma grade. MATERIALS AND METHODS: Seventy-six patients with gliomas underwent preoperative perfusion CT and assessment of relative CBV and permeability surface-area product. Regression analyses were performed to assess the rate of change between relative CBV and permeability surface-area product and to test whether these differed for distinct glioma grades. The ratio of relative CBV to permeability surface-area product was also computed and compared among glioma grades by using analysis of variance methods. RESULTS: The rate of change in relative CBV with respect to permeability surface-area product was highest for grade II gliomas followed by grade III and then grade IV (1.64 versus 0.91 versus 0.27, respectively). The difference in the rate of change was significant between grade III and IV (P = .003) and showed a trend for grades II and IV (P = .098). Relative CBV/permeability surface-area product ratios were the highest for grade II and lowest for grade IV. The pair-wise difference among all 3 groups was significant (P < .001). CONCLUSIONS: There is an increase in relative CBV more than permeability surface-area product in lower grade gliomas, whereas in grade III and especially grade IV gliomas, permeability surface-area product increases much more than relative CBV. The rate of change of relative CBV with respect to permeability surface-area product and relative CBV/permeability surface-area product ratio can serve as an imaging correlate to changes occurring at the tumor microvasculature level.